Near-critical phenomena in intracellular metabolite pools

The supply and consumption of metabolites in living cells are catalyzed by enzymes. Here we consider two of the simplest schemes where one substrate is eliminated through Michaelis-Menten kinetics, and where two types of substrates are joined together by an enzyme. It is demonstrated how steady-state substrate concentrations can change ultrasensitively in response to changes in their supply rates and how this is coupled to slow relaxation back to steady state after a perturbation. In the one-substrate system, such near-critical behavior occurs when the supply rate approaches the maximal elimination rate, and in the two-substrate system it occurs when the rates of substrate supply are almost balanced. As systems that operate near criticality tend to display large random fluctuations, we also carried out a stochastic analysis using analytical approximations of master equations and compared the results with molecular-level Monte Carlo simulations. It was found that the significance of random fluctuations was directly coupled to the steady-state sensitivity and that the two substrates can fluctuate greatly because they are anticorrelated in such a way that the product formation rate displays only small variation. Basic relations are highlighted and biological implications are discussed.     

Double Knockout Mutants of Arabidopsis Grown under Normal Conditions Reveal that the Plastidial Phosphorylase Isozyme Participates in Transitory Starch Metabolism

In leaves of two starch-related single-knockout lines lacking either the cytosolic transglucosidase (also designated as disproportionating enzyme 2, DPE2) or the maltose transporter (MEX1), the activity of the plastidial phosphorylase isozyme (PHS1) is increased. In both mutants, metabolism of starch-derived maltose is impaired but inhibition is effective at different subcellular sites. Two constitutive double knockout mutants were generated (designated as dpe2-1 × phs1a and mex1 × phs1b) both lacking functional PHS1. They reveal that in normally grown plants, the plastidial phosphorylase isozyme participates in transitory starch degradation and that the central carbon metabolism is closely integrated into the entire cell biology. All plants were grown either under continuous illumination or in a light-dark regime. Both double mutants were compromised in growth and, compared with the single knockout plants, possess less average leaf starch when grown in a light-dark regime. Starch and chlorophyll contents decline with leaf age. As revealed by transmission electron microscopy, mesophyll cells degrade chloroplasts, but degradation is not observed in plants grown under continuous illumination. The two double mutants possess similar but not identical phenotypes. When grown in a light-dark regime, mesophyll chloroplasts of dpe2-1 × phs1a contain a single starch granule but under continuous illumination more granules per chloroplast are formed. The other double mutant synthesizes more granules under either growth condition. In continuous light, growth of both double mutants is similar to that of the parental single knockout lines. Metabolite profiles and oligoglucan patterns differ largely in the two double mutants.During the last two decades, biochemical analyses of starch metabolism in higher plants have been favored by the availability of large sets of insertion mutants deficient in a single starch-related gene product. Based on phenotypical characterization of these mutants followed by the identification of the respective locus in the genome, novel starch-related proteins were discovered that reside inside the plastid, in the cytosol, in the nucleus, and in the plastidial envelope membranes. Taken together, these results have largely altered the current view on starch metabolism (Zeeman et al., 2010; Fettke et al., 2012a; Smith, 2012).Despite this progress, phenotypical analyses of starch-related mutants are complex and, under certain circumstances, yield misleading conclusions. Loss of function of metabolic steps may cause the entire starch synthesizing or degrading process to become nonfunctional. In this case, mutants are expected to have starch levels that are significantly altered. If, however, single knockout mutants are capable of partially or fully compensating the loss of function by other routes, the resulting phenotypes are less obvious and more difficult to predict. Carbon fluxes through existing paths may be enhanced, or novel metabolic routes may be established that compensate the lost function. As an example, leaves of Arabidopsis (Arabidopsis thaliana) mutants constitutively lacking the plastidial hexose-phosphate isomerase strongly express a distinct plastidial Glc-6-P/orthophosphate antiporter isoform that in wild-type plants is found only in heterotrophic tissues (Kunz et al., 2010). In mesophyll cells of the mutant, the reductive pentose phosphate cycle cannot drive assimilatory starch biosynthesis, as chloroplasts are unable to convert Fru-6-P to Glc-6-P. However, their capacity of transporting Glc-6-P between the cytosolic and the chloroplastic compartment is strongly increased. Furthermore, nonfunctionality of some starch-related proteins can lead to enlarged or diminished metabolite pools that via sensing processes, lead to cellular alterations distant from central carbon metabolism. This complexity is evidenced by several starch-related Arabidopsis mutants that possess a largely altered plastidial ultrastructure and exhibit premature degradation of the entire chloroplast (Stettler et al., 2009; Cho et al., 2011).Furthermore, several starch-related enzymes are capable of forming homomeric or heteromeric complexes that are functionally relevant but, to some extent, variable (Delatte et al., 2005; Utsumi and Nakamura, 2006; Kubo et al., 2010; Emes and Tetlow, 2012; Nakamura et al., 2012; Streb et al., 2012).In starch or glycogen storing prokaryotic and eukaryotic cells, α-glucan phosphorylase (EC 2.4.1.1) is common. Initially, this enzyme was considered to be the main starch synthesizing activity (Hanes, 1940). Later, both starch and glycogen synthases have been discovered that utilize either ADPglucose or UDPglucose (or both; Deschamps et al., 2006) as hexosyl donor. Ample evidence has been presented that these enzymes are essential biosynthetic enzymes (Ballicora et al., 2003; Zeeman et al., 2010; Roach et al., 2012; Palm et al., 2013). Furthermore, it is widely accepted that in glycogen-storing cells, phosphorylase is indispensible for the degradation of the storage polysaccharide (Hwang et al., 1989; Alonso-Casajús et al., 2006; Wilson et al., 2010; Roach et al., 2012; Gazzerro et al., 2013).In plant cells, the metabolic function of phosphorylase is more complex and far from being clear. In lower and higher plants, two distinct phosphorylase types exist as plastid- and cytosol-specific isozymes and are designated as Pho1 (or, in Arabidopsis, PHS1) and Pho2 (PHS2), respectively. Based on the large differences in the affinities for glycogen, the plastidial and the cytosolic phosphorylases are also named as low-affinity (L-type) and high-affinity (H-type) isozymes, respectively. As starch is restricted to the plastids, only the Pho1 (PHS1) type appears to possess direct access to native starch and/or plastidial starch-derived α-glucans.Conflicting phenotypical features have been reported for several mutants possessing altered levels of the plastidial phosphorylase isozyme(s). In the starch-related mutant4 of the unicellular green alga Chlamydomonas reinhardtii, the lack of one plastidial Pho1 isozyme (designated as PhoB) was associated with a lower cellular starch content, abnormally shaped granules, a modified amylopectin structure, and an elevated amylose-to-amylopectin ratio when the cells were kept under nitrogen limitation (Dauvillée et al., 2006). These phenotypical features suggest an involvement of the plastidial phosphorylase PhoB in the biosynthesis of a storage polysaccharide resembling the reserve starch of higher plants. Similarly, a rapid incorporation of ¹⁴C into starch was observed when tuber discs from various transgenic potato lines were incubated with [U-¹⁴C]Glc-1-P. The rate of starch labeling was found to reflect the activity of the plastidial phosphorylase isozyme Pho1 (Fettke et al., 2010, 2012b). By contrast, transgenic potato (Solanum tuberosum) lines have been generated that due to expression of an antisense construct, possess a largely diminished total Pho1 activity in leaves. Leaf starch content is essentially unchanged compared with that of the wild-type plants, suggesting that under normal growth conditions, the plastidial phosphorylase is not necessarily involved in starch metabolism or, alternatively, can easily be replaced by other enzymes (Sonnewald et al., 1995). Likewise, the phenotype (including leaf starch content) of an Arabidopsis mutant lacking functional PHS1 has been reported not to differ from the wild type when the plants were grown under normal conditions. However, under water stress conditions, significantly more local leaf lesions have been reported to occur (Zeeman et al., 2004).When leaf discs from bean (Phaseolus vulgaris) or Arabidopsis plants were exposed to conditions favoring photorespiration (i.e. an atmosphere consisting of 30% [v/v] O₂ and 70% [v/v] N₂ but lacking CO₂), transitory starch was degraded in the light at a high rate and the plastidial Glc-6-P pool increased. In Arabidopsis mutants deficient in PHS1, the Glc monophosphate pool did not respond to photorespiratory conditions (Weise et al., 2006). These data lead to the conclusion that in illuminated leaves with very high rates of photorespiration, PHS1 is involved in the conversion of starch to Glc monophosphates but does not to participate in the nocturnal starch degradation.When studying several starch-related Arabidopsis mutants, we noticed that two single knockout mutations that both affect the maltose metabolism but differ in the subcellular location of the target protein possess a significantly increased PHS1 activity (Malinova et al., 2011a, 2011b). One mutant constitutively lacks the functional cytosolic transglucosidase (also designated as disproportionating enzyme2; DPE2) and, therefore, the cytosolic route of starch-derived maltose metabolism is impaired (Chia et al., 2004; Lu and Sharkey, 2004). The other mutant does not express the plastidial maltose transporter MEX1, resulting in a massively enlarged maltose pool (Niittylä et al., 2004). Thus, in the two mutants, the metabolism of starch-derived maltose is blocked at different subcellular sites, i.e. the cytosol and the chloroplast. The enhanced PHS1 activity as observed for the two mutants is difficult to explain unless a more general function of the phosphorylase isozyme in starch metabolism is assumed.For a detailed functional analysis of PHS1-related processes, we generated two types of constitutive PHS1-deficient double knockout mutants (DPE2 plus PHS1 or MEX1 plus PHS1) and studied their phenotypes in more detail under various experimental conditions. Shoot growth and leaf chlorophyll content are reduced when the plants are grown under a light-dark regime, but under continuous illumination, both effects are far less pronounced. Based on these data, we propose that the plastidial phosphorylase participates in both the turnover of transitory starch and in the maintenance of intact chloroplasts.     

Mutation of Threonine 34 in Mouse Podoplanin-Fc Reduces CLEC-2 Binding and Toxicity in Vivo While Retaining Anti-lymphangiogenic Activity

The lymphatic system plays an important role in cancer metastasis and inhibition of lymphangiogenesis could be valuable in fighting cancer dissemination. Podoplanin (Pdpn) is a small, transmembrane glycoprotein expressed on the surface of lymphatic endothelial cells (LEC). During mouse development, binding of Pdpn to the C-type lectin-like receptor 2 (CLEC-2) on platelets is critical for the separation of the lymphatic and blood vascular systems. Competitive inhibition of Pdpn functions with a soluble form of the protein, Pdpn-Fc, leads to reduced lymphangiogenesis in vitro and in vivo. However, the transgenic overexpression of human Pdpn-Fc in mouse skin causes disseminated intravascular coagulation due to platelet activation via CLEC-2. In the present study, we produced and characterized a mutant form of mouse Pdpn-Fc, in which threonine 34, which is considered essential for CLEC-2 binding, was mutated to alanine (PdpnT34A-Fc). Indeed, PdpnT34A-Fc displayed a 30-fold reduced binding affinity for CLEC-2 compared with Pdpn-Fc. This also translated into fewer side effects due to platelet activation in vivo. Mice showed less prolonged bleeding time and fewer embolized vessels in the liver, when PdpnT34A-Fc was injected intravenously. However, PdpnT34A-Fc was still as active as wild-type Pdpn-Fc in inhibiting lymphangiogenesis in vitro and also inhibited lymphangiogenesis in vivo. These data suggest that the function of Pdpn in lymphangiogenesis does not depend on threonine 34 in the CLEC-2 binding domain and that PdpnT34A-Fc might be an improved inhibitor of lymphangiogenesis with fewer toxic side effects.     

TLR2 Mediates Recognition of Live Staphylococcus epidermidis and Clearance of Bacteremia

Background

Staphylococcus epidermidis (SE) is a nosocomial pathogen that causes catheter-associated bacteremia in the immunocompromised, including those at the extremes of age, motivating study of host clearance mechanisms. SE-derived soluble components engage TLR2; but additional signaling pathways have also been implicated, and TLR2 can play complex, at times detrimental, roles in host defense against other Staphylococcal spp. The role of TLR2 in responses of primary blood leukocytes to live SE and in clearance of SE bacteremia, the most common clinical manifestation of SE infection, is unknown.

Methodology/Principal Findings

We studied TLR2-mediated recognition of live clinical SE strain 1457 employing TLR2-transfected cells, neutralizing anti-TLR antibodies and TLR2-deficient mice. TLR2 mediated SE-induced cytokine production in human embryonic kidney cells, human whole blood and murine primary macrophages, in part via recognition of a soluble TLR2 agonist. After i.v. challenge with SE, early (1 h) cytokine/chemokine production and subsequent clearance of bacteremia (24–48 h) were markedly impaired in TLR2-deficient mice.

Conclusions/Significance

TLR2 mediates recognition of live SE and clearance of SE bacteremia in vivo.     

The external anion binding site of the human erythrocyte anion transporter: DNDS binding and competition with chloride

Summary The interaction between chloride and the anion transport inhibitor DNDS (4,4-dinitro stilbene-2,2-disulfonate) at the external anion binding site of the human erythrocyte anion transporter was examined by two techniques: a) chloride tracer flux experiments in the presence of varying concentrations of DNDS, and b) DNDS equilibrium binding experiments in the presence of varying concentrations of intracellular and extracellular chloride, Cl _i and Cl _o . DNDS inhibited competitively the Cl _o -stimulated chloride efflux from intact red cells at 0°C and pH 7.8 with an inhibitor constant of 90nm. Under the same conditions DNDS bound reversibly to one class of binding sites on intact cells with a capacity of 8.5×10⁵ molecules/cell. Cl _o competitively inhibited DNDS binding with an inhibitor constant of 6mm. In the absence of Cl _o the DNDS binding constant was 84mm. The competition between chloride and DNDS was also tested in nystatintreated cells in which Cl _o always equaled Cl _i . Under these conditions the values of the DNDS binding constant and the chloride inhibitor constant were significantly larger. All these data were in quantitative agreement with a single-site, alternating access kinetic scheme with ping-pong-type kinetics that we have previously developed for modeling chloride exchange transport. The data also served to rule out special cases of an alternative two-sited sequential-type kinetic scheme. DNDS binding experiments were also performed at 10 and 20°C. We found that neither the DNDS binding constant nor the Cl _o inhibitor constant were significantly changed compared to 0°C.     

TEMPERATURE AND HEART RATE IN PTEROTRACHEA AND TIEDEMANNIA

1. For the heart rate in Pterotrachea coronata, intermediate temperatures disclose a thermal increment of 11,200 ±. This value is identical with the one reported by Crozier and Stier for the lamelli-branch, Anodonta. In the pteropod, Tiedemannia neapolitana the same temperatures typically reveal in the heart rate a µ value of 16,200 ± This agrees quantitatively with 16,300 found by Crozier and Stier for the heart of the slug, Limax maximus. 2. At high temperatures the average value of µ for Pterotrachea is 7,300: for Tiedemannia, 7,400. The corresponding averages at the lower limits are 22,000 and 23,000. 3. The great variability found near the edges of the temperature field are explicable in two ways. During intermissions characteristic of high temperatures and occurring also at low, we can assume a restorative process; while at both the upper and lower limits we may, in addition, find that reactions assume control which under ordinary circumstances never do so. Special evidence indicates that the highest temperatures employed, 27°C., and the lowest, 4°C., caused no irreversible changes in mechanism. 4. The theoretical analysis of the experimental facts makes use of Meyerhof''s conception of carbohydrate metabolism and projects the cyclical nature of rhythm into the substrate of control. Assuming as a source of energy an original supply of material O, the value of 22,000 ± is assigned provisionally to a mobilization hydrolysis while 11,200 ± and 16,000 ± are attached to oxidative reactions influenced respectively by OH'' and possibly Fe, or some other catalyst. The lowest value, 7,300 ± is assumed to indicate a synthetic process (lactic acid → glycogen?), possibly limited by CO₂ excretion. In the present state of our knowledge, this distribution and interpretation seems to account reasonably for the experimental facts, but until we know more about the neurogenic controls, is entitled to rank only as an hypothesis.     

Aryltetralone and arylindanone neolignans from Virola sebifera

The fruits of Virola sebifera contain several tetralone neolignans, including 2,4-dihydroxy-6,7-methylenedioxy-2,3-dimethyl-4-veratryltetralin-1-one. The 3-hydroxylated derivative of this compound may undergo a biosynthetic pinacol-pinacolone rearrangement to give 2-acetyl-3-hydroxy-2-methyl-5,6-methylenedioxy-3-veratrylindan-1-one which, together with other indanone neolignans, was also isolated.     

Intrathoracic versus Cervical Anastomosis after Resection of Esophageal Cancer: A matched pair analysis of 72 patients in a single center study

ABSTRACT: BACKGROUND: The aim of this study was to analyze the early postoperative outcome of esophageal cancer treated by subtotal esophageal resection, gastric interposition and either intrathoracic or cervical anastomosis in a single center study. METHODS: 72 patients who received either a cervical or intrathoracic anastomosis after esophageal resection for esophageal cancer were matched by age and tumor stage. Collected data from these patients were analyzed retrospectively regarding morbidity and mortality rates. RESULTS: Anastomotic leakage rate was significantly lower in the intrathoracic anastomosis group than in the cervical anastomosis group (4 of 36 patients (11 %) vs. 11 of 36 patients (31 %); p = 0.040). The hospital stay was significantly shorter in the intrathoracic anastomosis group compared to the cervical anastomosis group (14 (range 10-110) vs. 26 days (range 12 - 105); p = 0.012). Wound infection and temporary paresis of the recurrent laryngeal nerve occurred significantly more often in the cervical anastomosis group compared to the intrathoracic anastomosis group (28 % vs. 0 %; p = 0.002 and 11 % vs. 0 %; p = 0.046). The overall Inhospital mortality rate was 6 % (4 of 72 patients) without any differences between the study groups. CONCLUSIONS: The present data support the assumption that the transthoracic approach with an intrathoracic anastomosis compared to a cervical esophagogastrostomy is the safer and more beneficial procedure in patients with carcinoma of the lower and middle third of the esophagus due to a significant reduction of anastomotic leakage, wound infection, paresis of the recurrent laryngeal nerve and shorter hospital stay.     

Effect of exogenous circulating anti-bPL antibodies on bovine placental lactogen measurements in foetal samples

Background  

The involvement of placental lactogen (PL) in the regulation of foetal growth has been investigated in different species by in vivo immunomodulation techniques. However, when circulating antibodies are present together with the hormone, the procedure for hormonal measurement becomes considerably complex. The aim of this study was the immunoneutralization of bovine placental lactogen (bPL) concentrations in bovine foetal circulation by direct infusion of rabbit anti-bPL purified immunoglobulins (IgG) via a foetal catheter (in vivo study). The ability of a RIA based on guinea pig anti-bPL antiserum, for the measurement of bPL concentrations in samples containing exogenous rabbit anti-bPL immunoglobulins, was also analyzed in in vitro and in vivo conditions.     

About PAR: the distinct evolutionary dynamics of the pseudoautosomal region

Sex chromosomes differ from other chromosomes in the striking divergence they often show in size, structure, and gene content. Not only do they possess genes controlling sex determination that are restricted to either the X or Y (or Z or W) chromosomes, but in many taxa they also include recombining regions. In these 'pseudoautosomal regions' (PARs), sequence homology is maintained by meiotic pairing and exchange in the heterogametic sex. PARs are unique genomic regions, exhibiting some features of autosomes, but they are also influenced by their partial sex linkage. Here we review the distribution and structure of PARs among animals and plants, the theoretical predictions concerning their evolutionary dynamics, the reasons for their persistence, and the diversity and content of genes that reside within them. It is now clear that the evolution of the PAR differs in important ways from that of genes in either the non-recombining regions of sex chromosomes or the autosomes.